DE102011076451A1 - Locking of an electric vehicle - Google Patents

Abstract

To prevent damage to a cable set used to charge an electric vehicle if the vehicle is driven away while the cable set is connected, a lock can be provided to lock the vehicle. Such locking can be based on the fact that a protective flap above the charging receptacle is open, or on the detection that a cable set is inserted. However, in one embodiment of the disclosure, if the vehicle is in an activated state, the lock is prevented from locking the vehicle. That is, an undesirable locking of the vehicle is prevented if either there is no indication that a cable set is coupled to the vehicle or the vehicle is in an activated state.

Description

The present disclosure relates to interlocks with respect to the charging system on electric vehicles for inhibiting vehicle travel during charging.

Electric vehicles that are coupled to a wall outlet to charge the battery are sometimes equipped with a latch that prevents vehicle starting when the harness of the electric vehicle is plugged into the wall. Since the vehicle may be subject to turbocharging, there is a fear that the harness and / or vehicle would be damaged in the event of driving away while the harness is connected.

The latch may be a switch coupled to a protective flap over the receptacle of the vehicle. If the switch indicates that the door is open, driving away is prevented. In another alternative, an electronic control unit (ECU) on board the vehicle determines whether the harness is connected and, in this case, prevents it from going away.

It may be possible for a vandal or other third party to interfere with the operability of the vehicle by opening the protective door or inserting a device into the receptacle of the vehicle to deceive the logic associated with the cable set of the ECU. Such a situation is not only inconvenient for the vehicle operator, but could leave the vehicle operator stranded when the vehicle operator can not detect the vehicle operation preventing problem.

To overcome at least one of these problems, a latch for a plug-in vehicle, also called a plug-in vehicle, when a negative result is detected by a cable set indicator, includes releasing the vehicle when a positive result from the cable set indicator is instantaneous Following detection of a negative result from the harness indicator is detected while the vehicle is continuously activated, and locking the vehicle when a positive result from a harness indicator is detected while the vehicle is deactivated. In one embodiment, releasing a power train of the vehicle allows wheels of the vehicle to be driven in response to a response of the vehicle operator to activate the vehicle. In one embodiment, an activated state of the vehicle is present when the vehicle is in a torque producing mode. Alternatively, the activated state includes that a transmission of the vehicle is in a forward or reverse drive.

The vehicle has at least one electric motor coupled to vehicle wheels, and locking of the vehicle is performed by preventing the electric motor from supplying driving force to the vehicle wheels. The vehicle may further include an internal combustion engine coupled to vehicle wheels. The locking of the vehicle may further include preventing the engine from supplying motive power to vehicle wheels.

The vehicle has a charging receptacle with a protective flap that allows access to the charging receptacle and a switch mounted near the protective flap. The switch includes the harness indicator, or the harness indicator is provided by the switch. Alternatively, the harness indicator is based on detecting electrical characteristics consistent with a harness being coupled to the receptacle on the vehicle.

A latch for a plug-in vehicle includes a cable set indicator and an electronic control unit coupled to a power train of the vehicle and the cable set indicator. An electronic control unit locking routine inhibits power transmission when the harness indicator indicates that a charging cable is connected to the vehicle and the vehicle is deactivated, and inhibits power transmission inhibition when the vehicle is activated. The vehicle is activated when the vehicle is in a torque producing mode such that an operator of the vehicle can selectively command drive to vehicle wheels without tampering with the harness indicator. The latch may also include a charge receptacle coupled to the vehicle, a loading flap coupled to the vehicle that prevents access to the charge receptacle when in a closed position, and a charge flap coupled to the vehicle and switches electronically coupled to the electronic control unit. A signal from the switch indicates whether the door is open or closed and the switch is the cable set indicator. In an alternative embodiment, the latch includes a charge receptacle coupled to the vehicle and electronically coupled to the electronic control unit. The electronic control unit detects whether a plug is coupled to the receptacle, and the detection of the plug is the cable set indicator. The electronic control unit prevents the vehicle from being locked when the vehicle is being activated, regardless of a status of the harness indicator. The latch may further include a charge receptacle coupled to the vehicle and electronically coupled to the electronic control unit and an operator display unit in a passenger compartment of the vehicle. The electronic control unit turns on the operator display unit when the cable set indicator indicates that a tether is coupled to the charge receptacle.

According to an alternative embodiment, a locking method for a plug-in vehicle includes preventing access of the vehicle to a torque producing mode when a positive result from a harness indicator is detected and, in addition, the vehicle is in a deactivated state; and allowing access of the vehicle to the torque producing mode in response to one of the following alternatives: a negative result from a harness indicator and the vehicle is currently in an activated state. The torque producing mode is prevented by inhibiting power transmission of the vehicle or preventing access of a vehicle-coupled transmission to any forward or reverse gear. The vehicle has a receptacle adapted to receive a harness for charging the vehicle, the vehicle has a protective flap to cover the receptacle, the vehicle has a switch near the protective flap, and the harness indicator is based on a signal from the switch. indicating whether the protective flap is open. Alternatively, the vehicle has a receptacle configured to receive a harness for charging the vehicle, and the harness indicator is based on detecting the presence of the harness coupled to the receptacle.

The torque producing mode is a mode in which the vehicle can be driven by commands from a vehicle operator by operating an accelerator pedal coupled to the vehicle. According to another embodiment, the torque producing mode is a state of the vehicle in which a vehicle operator selectively commands a power transmission of the vehicle to drive the vehicle.

The figures show:

1 is a diagram of a plug-in hybrid electric vehicle; and

2 FIG. 10 is a flowchart of one embodiment of the present disclosure. FIG.

As will be understood by one of ordinary skill in the art, various features of the embodiments illustrated and described with respect to any of the figures may be combined with features illustrated in one or more other figures to produce alternative embodiments that are not explicitly illustrated and described , The combinations of illustrated features provide representative embodiments for typical applications. However, for certain applications or implementations, various combinations and modifications of features consistent with the teachings of the present disclosure may be desired. Those of ordinary skill in the art may recognize similar applications or implementations consistent with the present disclosure, e.g. For example, those in which components are arranged in a slightly different order than in the embodiments shown in the figures. It will be appreciated by those of ordinary skill in the art that the teachings of the present disclosure may be applied to other applications or implementations. In 1 is a diagram of a vehicle as an example as a plug-in hybrid electric vehicle (HEV), also called plug-in hybrid vehicle, 10 shown. One type of HEV involves power transmission 11 : an internal combustion engine, a one-way clutch 14 , a generator 16 , a planetary gear 18 and a motor 20 , The power transmission 11 is with the differential 22 coupled. The differential 22 is coupled to the axle, the drive wheels 24 having. The vehicle 10 also has non-driven wheels 26 ,

The HEV in 1 has a high voltage battery 28 that with the generator 16 and the engine 20 is coupled. The electronic control unit (ECU) 30 is with the internal combustion engine 12 , the overrunning clutch 14 , the generator 16 , the engine 20 and the battery 28 coupled. In 1 is a single ECU 30 shown. However, it is common for the vehicle 10 distributed computing, involving several ECUs instead of a single ECU. For purposes of illustration and ease of description, data processing and control functionality will be described with reference to a single ECU, with the understanding that such functionality may be shared among multiple processors.

The vehicle 10 has a plug-in vehicle electric recording 32 with a protective flap 34 , in the 1 is shown in an open position. The vehicle 10 owns a charging device that in 1 in the electric recording 32 integrated, but could also be in a separate module in an alternative embodiment. On the vehicle 10 near the protective flap 34 is a pin switch 35 intended. The protective flap 34 keeps away from dirt, dust and moisture from the environment when no charge takes place. A charging cable set 36 includes: an electrical coupler 38 who is using while loading the recording 32 is coupled; two sections of cable 40 with a facility of electric vehicle supply equipment (EVSE) 42 between the cables 40 , In certain embodiments, the EVSE 42 Fuses, relays, transformers and a printed circuit board with processing capability. The cable set 36 further includes a plug 44 in the wall socket 46 can be inserted.

The vehicle 10 in 1 is an HEV, in an alternative embodiment is the vehicle 10 however, a battery-only electric vehicle. Furthermore, other HEV architectures are within the scope of the present disclosure.

The cable set 36 can be damaged if the vehicle 10 put into operation and would be driven away when the harness 36 on the vehicle 10 is coupled. In order to avoid such damage, a locking system may be provided where the ECU 30 in response to a harness indicator, that is, indicating whether a harness is coupled to the vehicle, the power transmission 11 prevents you from driving away. In one embodiment, the two position pen switch is shown 35 The ECU indicates whether the flap is open or closed. The opening of the flap indicates that a harness is coupled to the vehicle. In embodiments where the flap is used as the loading indicator, locking actions take place regardless of whether a harness is actually coupled to the vehicle and whether actual loading is taking place or not. In certain embodiments, the ECU performs 30 an operator display unit 50 a signal so that the operator of the vehicle is informed and can take care of the error. The operator display unit 50 may provide a written, symbolic, verbal, or any suitable signal to the operator of the vehicle 10 to display an error.

In an alternative embodiment, the ECU detects 30 whether an electrical coupler with the recording 32 is coupled. This can be done via a switch near the receptacle 32 similar to the pen switch 35 be achieved, the electrical coupler 38 pressed when installed. In another embodiment, the ECU detects 30 on the basis of electrical properties, whether a harness with the receptacle 32 is coupled. Pressing one with the recording 32 associated stylus or electrical properties are one embodiment of a harness indicator. As with the flap switch 35 can be a pen switch near the receptacle 32 , which indicates the presence of an electrical coupler or the change of certain electrical characteristics, are used as a harness indicator. An accidental push of the stylus or an alternative to the electrical coupler 38 can with the recording 32 both would provide a positive result in the harness indicator, regardless of whether a harness is actually coupled to the vehicle or not. An alternative to the electrical coupler 38 could include an element that has one or more components associated with the receptacle 32 and the electrical characteristics of the cable set 36 imitate, so the ECU 30 detects the presence of a cable set. For example, the element may be related to the resistance characteristics of the cable set 36 to match.

As the flap 34 and the recording 32 outside the vehicle 10 a joker can find the vehicle in embodiments where the flap 34 provides the harness indicator signal, or locks the vehicle by plugging in an electrical connector that contains certain circuitry to provide a cable set indication. Or an innocent third party may inadvertently lock the vehicle by z. B. Forgets, the flap 34 when disconnecting the cable set 36 close or with clothes on the flap 34 gets stuck so that it opens. In another example, a small sheet metal damage may cause the protective flap 34 opens and thereby the vehicle 10 is locked. If the vehicle 10 For example, parked in a garage gives the operator display unit 50 the operator information about the resolution of the situation that prevents the vehicle 10 drives away. However, such locking poses a problem when the vehicle 10 is activated. If the vehicle 10 for example, stopped at a traffic light and a pedestrian jostles the car and causes the protective flap 34 opens, the vehicle becomes 10 locked, which is at least inconvenient for the vehicle operator. It is desirable to prevent the locking of the vehicle 10 locks if it is already activated, ie a condition under which it is extremely unlikely that a harness is inserted. If the harness indicator provides a positive result in such circumstances, it is most likely a false indication that a harness is actually with the vehicle 10 is coupled. Instead, it may provide a positive result by having the door open or a dummy plug coupled to the vehicle seat, ie a false positive result.

In 2 begins a flowchart according to an embodiment of the disclosure in 100 , In the block 102 it is determined whether the vehicle is activated. In one embodiment, an activated vehicle occurs at key-on, ie, the operator of the vehicle has used a key of the vehicle to bring the vehicle into a state could cause the vehicle to move when a gear is accessed and an accelerator pedal is depressed. Certain vehicles are not equipped with an ignition key, but are instead started with a push button, which is only allowed when the ignition system detects a radio frequency identification device with the corresponding code in the vehicle or other suitable device and the operator actuates a button to activate the vehicle Has. In such a case, key-on refers to the condition in which the vehicle operator could cause the vehicle to move by accessing a gear and depressing an accelerator pedal. Such an activated state is independent of whether an electric motor or an internal combustion engine associated with the vehicle rotates. For example, neither the electric motor nor the internal combustion engine may turn when provided in the vehicle when the vehicle has stopped at a traffic light. Nevertheless, the vehicle is considered to be activated because the operator can request driving by simply depressing the accelerator pedal (without applying the brake). Such an activated state may alternatively be referred to as a torque producing mode or a ready to drive mode. A blocking of the vehicle in this case refers to the fact that the vehicle is incapacitated to drive the vehicle via normal operator actions. Normal operator actions are those that cause the vehicle to access the torque producing mode, such as engaging a gear, releasing a brake pedal, and / or depressing an accelerator pedal. In background systems, the vehicle is locked when a lockup condition occurs and is not released until the lockup condition is removed. The vehicle can be released again by the operator taking care of the situation leading to the locked state. However, for purposes of the present disclosure, such actions to overcome the lockup condition are not considered to be normal operator actions for placing the vehicle in the torque producing mode. Further, such normal operator actions do not include the vehicle operator or other actor taking actions from outside a passenger compartment of the vehicle. Such abnormal actions occurring outside the passenger compartment would be, for example, removal of the harness 36 and closing the protective cover 34 ,

Again with respect to 2 is at a positive result in 102 the controller 104 in which an indication of one with the recording 32 coupled cable set 36 is detected. When such an indication is found, control is sent to the block 106 in which a warning message is displayed on the operator display unit. Such a message may be a text message, an oral message, a bell, an indicator light, and so on. A negative result in the block 104 and 106 indicates the control 108 where blocking is prevented and the vehicle is allowed to remain activated.

If there is a negative result in the block 102 the controller is connected to block 110 delivered in the harness coupling with the receptacle 32 is determined. For a positive result in the block 110 the controller is connected to block 112 delivered, in which the lock is actuated, which means that the vehicle is locked. In one embodiment, the vehicle is locked by inhibiting power transmission, ie, neither the engine nor the engine can be rotated. In another embodiment, the transmission may be allowed to rotate to provide secondary functions, but the vehicle is locked by preventing the transmission from being removed from the park position. From block 112 off the control is on 114 in which it is determined whether a start attempt has taken place. If so, the operator display unit message is in the block 116 activated to give the operator information about the error so that the operator can rectify the situation and remove the condition leading to the blocking. If there is a negative result in the block 114 the controller is connected to block 118 in which the loading of the vehicle is allowed.

If there is a negative result in the block 110 the controller is connected to block 120 in which the lock is not activated so that the vehicle may be started (released) when such a command is given by the vehicle operator. The routine may be successive, with control of any of the blocks 108 . 118 and 120 off again to the block 102 is delivered.

Although the best mode of execution has been described in detail, various alternative designs and embodiments within the scope of the following claims will be apparent to those skilled in the art. When one or more embodiments have been described as providing benefits or advantages over other embodiments and / or the prior art with respect to one or more desired characteristics, it will be apparent to those of ordinary skill in the art that trade-offs can be made among various features to achieve desired system attributes that may depend on the specific application or implementation. These attributes include, but are not limited to: cost, load capacity, durability, life cycle cost, marketability, appearance, packaging, size, reparability, weight, manufacturability, ease of assembly, etc. Depending on the application, a suitable compromise may be selected. The embodiments described as being less desirable relative to other embodiments with respect to one or more features are not outside the scope of the claimed disclosure.

Claims (10)

Locking procedure for a plugin vehicle, with the following steps: Releasing the vehicle when a negative result is detected by a harness indicator; Enabling the vehicle when a positive result from the harness indicator is detected immediately following detection of a negative result from the harness indicator while the vehicle is continuously activated; and Locking the vehicle when a positive result from a harness indicator is detected while the vehicle is deactivated. The method of claim 1, wherein enabling comprises permitting power transmission of the vehicle to drive wheels of the vehicle in response to an action of a vehicle operator to activate the vehicle. The locking method of claim 1, wherein the vehicle has at least one electric motor coupled to vehicle wheels and includes locking the vehicle to prevent the electric motor from supplying driving force to vehicle wheels. A latch according to claim 3, wherein the vehicle further comprises an internal combustion engine coupled to vehicle wheels, and further comprising blocking the vehicle to prevent the internal combustion engine from supplying motive power to drive wheels. Lock for a plug-in vehicle, comprising: a harness indicator; an electronic control unit coupled to a power train of the vehicle and the cable set indicator, wherein a locking routine of the electronic control unit disables the power transmission when the harness indicator indicates that a charging cable is connected to the vehicle and the vehicle is deactivated and inhibits power transmission inhibition the vehicle is activated. A latch according to claim 5, further comprising: a charge receptacle coupled to the vehicle; a tailgate coupled to the vehicle that prevents access to the load receptacle when in a closed position; a switch coupled to the tailgate and electronically coupled to the electronic control unit, wherein a signal from the switch indicates whether the door is open or closed, and the switch includes the harness indicator. A latch according to claim 5, further comprising: a charge receptacle coupled to the vehicle and electronically coupled to the electronic control unit, wherein the electronic control unit detects whether a plug is coupled to the charge receptacle and detection of the plug comprises the harness set indicator. A latch as claimed in claim 5, wherein the electronic control unit, regardless of a status of the cable set indicator, prevents the vehicle from being locked when the vehicle is currently activated. A latch according to claim 5, further comprising: a charge receptacle coupled to the vehicle and electronically coupled to the electronic control unit; and an operator display unit in a passenger compartment of the vehicle, wherein the operator display unit is electronically coupled to the electronic control unit, wherein the electronic control unit turns on the operator display unit when the harness indicator indicates that a connector is coupled to the charge receptacle. Locking procedure for a plugin vehicle, with the following steps: Preventing access of the vehicle to a torque producing mode when a positive result from a harness indicator is detected and the vehicle is also in a deactivated state; and Allowing the vehicle to access the torque producing mode in response to one of the following alternatives: a negative result from a harness indicator; and the vehicle is currently in an activated state.

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